Jim Sanduski, Vice President of strategic product marketing for Sharp Electronics, speaks in front of an ICC Purios Ultra HD television at their news conference during the Consumer Electronics Show (CES) in Las Vegas January 7, 2013. Sharp introduced new television technology and devices made with IGZO technology (Indium gallium zinc oxide) which promises ultra-high screen resolution with very low power usage. The TV is expected to ship in the summer of 2013. REUTERS/Steve Marcus

Yes, 8K. That means it has twice number of vertical columns of pixels and twice the number of horizontal rows of pixels as 4K TVs. That gives 8K TVs four times the resolution of 4K TVs and a whopping 16 times the resolution of regular HD sets.

While 4K sets are impressive enough in their own right, Sharp's 8K is amazing. Despite its large screen size, I had to get within an arm's length to start seeing its individual pixels. Even on smaller 4K televisions, you can start seeing their individual pixels farther away than that.

Sharp also had on display had two flexible OLEDs, which are manufactured on plastic rather than glass, allowing them to be bent and flexed like a playing card. Both are about the size of a playing card and run full-motion, full-color video.

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For someone like me -- I've long dreamed of a smart device that I could retract from the side of a pen or roll up and throw in my pocket -- it was neat to see the technology that might make that possible.

Still, 8K TVs and flexible OLED screens are likely years away from mass market consumer products. So it was exciting to see at Sharp's booth demos of a technology that may be in consumers' hands much sooner.

That technology is called Igzo. It's new semiconductor process that uses a combination of indium, gallium, zinc and oxygen (thus the name) in place of silicon. Sharp has started to use it in LCD displays and touch-screen elements.

Igzo transistors can be made smaller than those made of silicon and can move electrons faster. As a result, Igzo screens can be made much more power efficient and Igzo touch screens can be less susceptible to noise, allowing them to more accurately recognize when users touch them. An Igzo display also can hold an image much longer than a silicon-based one before having to be refreshed.

According to Sharp, the power savings can be in the neighborhood of 80 percent to 90 percent better than the standard display technologies. So a smartphone could last two days of typical use before its battery runs out -- about double the life of today's best smartphones.

And the smaller transistors can make for smaller pixels, leading to dramatically higher resolution screens. Already Sharp is offering a smartphone in the Japanese market that has a 443 pixel-per-inch screen. By contrast, Apple's (AAPL) iPhone 5 has a 326 pixel-per-inch screen.

So some neat stuff from Sharp. Here's hoping the company sticks around and continues its innovative streak.

On another front, many of us have gotten used to using our smartphones to navigate in our cars or to figure out how to walk from one building to another in a big city.

But the technology used by smartphones to offer directions is generally not effective indoors. GPS satellites often can't be seen inside and Wi-Fi radios, which also are used to find people's locations, are much more spotty in their coverage and much less precise.

But one company I met with at the Consumer Electronics Show is developing an interesting solution to this problem.

France-based Movea specializes in working with motion detectors such as gyroscopes, accelerometers and magnetometers. The company has helped tennis racket manufacturer Babolat develop a racket that can sense -- through a built-in motion sensor -- how players are swinging their rackets and hitting balls. The company has also developed software that captures full-body motion from a system of 15 motion sensors attached to various points on a person's body.

Now the company is applying that expertise to the problem of indoor navigation. It uses the motion sensors now commonplace in most smartphones and tablets to determine a person's position indoors using dead reckoning, which is the process of calculating one's current position by using a previously determined position.

Using a prototype app, Dave Rothenberg, Movea's director of marketing, showed how the device can start from a known location, like a hotel lobby, and help a user navigate through a hallway, up an elevator and onto another floor, plotting the movements on a map.

The system detects a user's steps, estimates stride length and taps into magnetometers to get users' compass direction. If there's a pressure sensor present, such as on some newer Android-based phones, the system can estimate the floor of a building a person happens to be on.

The system worked fairly well in our demo, navigating us to within 10 feet of our destination without using the typical location sensors in the phone.

It was an interesting exploration of how you could use essentially the same technology used in Nintendo's Wii remotes to get around the mall.

Contact Troy Wolverton at 408-840-4285 or twolverton@mercurynews.com. Follow him at www.mercurynews.com/troy-wolverton or Twitter.com/troywolv.